Mixer Assembly Apparatus and Method

ABSTRACT

A mixing apparatus and system includes a hub, a plurality of blades, and a respective hinge for each blade to pivotally secure each blade to the hub. Each hinge including a lock having a tab and a detent to secure the respective blade in an operating conformation.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority to and is a continuation of U.S. patentapplication entitled, MIXER ASSEMBLY APPARATUS AND METHOD, filed Sep.14, 2012, having a Ser. No. 13/615,855, which claims the benefit of U.S.Patent Application entitled IMPELLER DEVICE AND SYSTEM, filed Jan. 24,2012, having a Ser. No. 61/590,188 the disclosure of which is herebyincorporated by reference in its entirety.

FIELD OF THE INVENTION

The present disclosure generally relates to an impeller. Moreparticularly, the present disclosure pertains to a folding impeller foruse in a mixing system or assembly that utilizes containers or vesselshaving relatively small openings for mixer insertion.

BACKGROUND

Mixing and blending applications, in particular the mixing and blendingof liquids, liquid suspensions and gases, are often constrained by thediameter of the tank in which the mixing is being carried out and by thediameter of the impeller. Moreover, the size and diameter of the manwaythrough which the impeller and shaft is inserted can further constrainthe mixing application and the impeller employed.

The impeller blades need to be inserted through the manway in the vesselfor installation. In some covered mixing vessels, manways are commonly24″ in size and can pass impeller blades of up to 23″ in width at best.Therefore, in order to insert larger blades, operators either have toinstall an oversized manway, or the blades must be supplied in alongitudinally split configuration and then assembled inside the vessel.Splitting the impeller blades is an expensive operation, especially forblades having a rounded, leading edge, twist and curvature. In addition,multiple bolts are required along with match marking to assure proper,gap free re-assembly. This process can be very difficult and timeconsuming because the inner and outer blade components must be alignedcorrectly so that the impeller balance and blade geometry will not becompromised.

Thus for vessels or containers with relatively small manways, it may beadvantageous to utilize a folding impeller as an alternative tosplitting the impeller blades or employing an oversized manway. However,conventional folding impellers suffer from a variety of deficiencies.For example, folding impellers must be held well away from the bottom ofthe container to reduce damage to the container and/or blades in thefolded position. Also, the folding mechanism of conventional impellerscauses serious disturbances in laminar flow of fluid around the impellerblades. Accordingly, it is desirable to provide an impeller that iscapable of overcoming the disadvantages described herein at least tosome extent.

SUMMARY

The foregoing needs are met, to a great extent, by embodiments thepresent disclosure, wherein in one respect an impeller is provided thatis capable of mixing fluids in a container.

An embodiment of the present invention relates to an attachment assemblyfor attaching an impeller system to a vessel or the like, comprising: aframe comprising: a first end and a second generally opposing oneanother; a first side that extends between said for and second ends; asecond side that extends between said first and second ends generallyparallel to the said first side; a first rotational rod having first andsecond ends that extends between said first and said second sides; and asecond rotational rod having first and second ends that extends betweensaid first and said second sides; a base plate disposed on said frame,wherein said base plate extends between said first and said second sidesand has a bore extending therethrough; a locking lever; a first bracketconnected to said locking lever and said first rotational rod; a secondbracket connected to said locking lever and said second rotational rod;a first latch mounted to said first rotational rod; and a second latchmounted to said second rotational rod.

Another embodiment pertains to an impeller drive assembly for driving amixing impeller or the like, comprising: an attachment assemblycomprising: a frame comprising: a first end and a second generallyopposing one another; a first side that extends between said for andsecond ends; a second side that extends between said first and secondends generally parallel to the said first side; a first rotational rodhaving first and second ends that extends between said first and saidsecond sides; and a second rotational rod having first and second endsthat extends between said first and said second sides; a base platehaving a bore disposed on said frame, wherein said base plate extendsbetween said first and said second sides; a locking lever; a firstbracket connected to said locking lever and said first rotational rod; asecond bracket connected to said locking lever and said secondrotational rod; a first latch mounted to said first rotational rod; anda second latch mounted to said second rotational rod; and a motorreleasably mounted to said attachment assembly.

Yet another embodiment relates to a method for attaching an impellerassembly to a vessel or the like, comprising: connecting an attachmentassembly to the vessel, the attachment assembly comprising: a framecomprising: a first end and a second generally opposing one another; afirst side that extends between said for and second ends; a second sidethat extends between said first and second ends generally parallel tothe said first side; a first rotational rod having first and second endsthat extends between said first and said second sides; and a secondrotational rod having first and second ends that extends between saidfirst and said second sides; a base plate having a bore disposed on saidframe, wherein said base plate extends between said first and saidsecond sides; a locking lever; a first bracket connected to said lockinglever and said first rotational rod; a second bracket connected to saidlocking lever and said second rotational rod; a first latch mounted tosaid first rotational rod; and a second latch mounted to said secondrotational rod; translating the locking lever to a first position,urging the first and second latch to engage the vessel; and mounting amotor to the base plate of the attachment assembly.

In yet another embodiment of the present invention, an attachmentassembly for attaching an impeller system to a vessel or the like,comprising: means for connecting an attachment assembly to the vessel,the attachment assembly comprising: a frame comprising: a first end anda second generally opposing one another; a first side that extendsbetween said for and second ends; a second side that extends betweensaid first and second ends generally parallel to the said first side; afirst rotational rod having first and second ends that extends betweensaid first and said second sides; and a second rotational rod havingfirst and second ends that extends between said first and said secondsides; a base plate having a bore disposed on said frame, wherein saidbase plate extends between said first and said second sides; a lockinglever; a first bracket connected to said locking lever and said firstrotational rod; a second bracket connected to said locking lever andsaid second rotational rod; a first latch mounted to said firstrotational rod; and a second latch mounted to said second rotationalrod; means for translating the locking lever to a first position, urgingthe first and second latch to engage the vessel; and means for mountinga motor to the base plate of the attachment assembly.

In another embodiment of the present invention, an impeller assembly, isdisclosed comprising: a hub; a first blade; a second blade; a firsthinge having a first tab and first detent connected to said hub, whereinsaid first hinge pivotally secures said first blade to said hub; asecond hinge having a second tab and a second detent connected to saidhub, wherein said second hinge pivotally secures said first blade tosaid hub.

In an embodiment of the present invention, an impeller assembly isdisclosed, comprising: a hub comprising: a first hinge integral theretohaving a first tab and first detent; and a second hinge integral theretohaving a first tab and first detent connected a first blade connected tosaid first hinge; and a second blade connected to said first hinge.

Another embodiment discloses a method of positioning an impeller into anoperating position, comprising: inserting the impeller in to a mixingvessel or the like, wherein the impeller comprises: a hub; a firstblade; a second blade; a first hinge having a first tab and first detentconnected to said hub, wherein said first hinge pivotally secures saidfirst blade to said hub; a second hinge having a second tab and a seconddetent connected to said hub, wherein said second hinge pivotallysecures said first blade to said hub; translating the first blade to theoperating position by pivoting the first blade whereby the first tabengages the first detent such that the first blade extends outwardlyfrom the hub; and translating the second blade to the operating positionby pivoting the second blade whereby the second tab engages the seconddetent such that the second blade extends outwardly from the hub.

In still another embodiment of the present invention, an impellerassembly is disclosed, comprising: means for inserting the impeller into a mixing vessel or the like, wherein the impeller comprises: a hub; afirst blade; a second blade; a first hinge having a first tab and firstdetent connected to said hub, wherein said first hinge pivotally securessaid first blade to said hub; a second hinge having a second tab and asecond detent connected to said hub, wherein said second hinge pivotallysecures said first blade to said hub; means for translating the firstblade to the operating position by pivoting the first blade whereby thefirst tab engages the first detent such that the first blade extendsoutwardly from the hub; and means for translating the second blade tothe operating position by pivoting the second blade whereby the secondtab engages the second detent such that the second blade extendsoutwardly from the hub.

In another embodiment of the present invention, an impeller assembly isdisclosed, comprising: a sleeve having a first end and a second end; abung hole closure sealingly disposed at the first end; and an impellerdisposed at the second end, the impeller comprising: a hub; a firstblade; a second blade; a first hinge having a first tab and first detentconnected to said hub, wherein said first hinge pivotally secures saidfirst blade to said hub; and a second hinge having a second tab and asecond detent connected to said hub, wherein said second hinge pivotallysecures said first blade to said hub.

In yet another embodiment, a mixing apparatus and system is disclosedcomprising: a vessel having a bung hole disposed on an upper surfacethereof; a motor attached to said vessel, wherein said motor has ahaving a shaft; an attachment assembly to attach the motor to thevessel; and an impeller assembly comprising: a sleeve having a first endand a second end, the shaft being configured to slide within the sleeve;a bung hole closure disposed at the first end, the bung hole closurebeing configured to mate with the bung hole; and a sleeve having a firstend and a second end; a bung hole closure sealingly disposed at thefirst end; and an impeller disposed at the second end, the impellercomprising: a hub; a first blade; a second blade; a first hinge having afirst tab and first detent connected to said hub, wherein said firsthinge pivotally secures said first blade to said hub; and a second hingehaving a second tab and a second detent connected to said hub, whereinsaid second hinge pivotally secures said first blade to said hub.

In still yet another invention of the present invention, a method formixing multiple components within a mixing vessel is disclosed,comprising: inserting an impeller assembly into the vessel, wherein theimpeller assembly comprises: a motor attached to said vessel, whereinsaid motor has a shaft; an attachment assembly to attach the motor tothe vessel; and a sleeve having a first end and a second end; a bunghole closure sealingly disposed at the first end; and an impellerdisposed at the second end, the impeller comprising: a hub; a firstblade; a second blade; a first hinge having a first tab and first detentconnected to said hub, wherein said first hinge pivotally secures saidfirst blade to said hub; and a second hinge having a second tab and asecond detent connected to said hub, wherein said second hinge pivotallysecures said first blade to said hub; translating the first blade to anoperating position by pivoting the first blade whereby the first tabengages the first detent such that the first blade extends outwardlyfrom the hub; and translating the second blade to the operating positionby pivoting the second blade whereby the second tab engages the seconddetent such that the second blade extends outwardly from the hub.

And finally, another embodiment of the present invention discloses amixing system apparatus, comprising: means for inserting an impellerassembly into the vessel, wherein the impeller assembly comprises: amotor attached to said vessel, wherein said motor has a shaft; anattachment assembly to attach the motor to the vessel; and a sleevehaving a first end and a second end; a bung hole closure sealinglydisposed at the first end; and an impeller disposed at the second end,the impeller comprising: a hub; a first blade; a second blade; a firsthinge having a first tab and first detent connected to said hub, whereinsaid first hinge pivotally secures said first blade to said hub; and asecond hinge having a second tab and a second detent connected to saidhub, wherein said second hinge pivotally secures said first blade tosaid hub. means for translating the first blade to an operating positionby pivoting the first blade whereby the first tab engages the firstdetent such that the first blade extends outwardly from the hub; and

means for translating the second blade to the operating position bypivoting the second blade whereby the second tab engages the seconddetent such that the second blade extends outwardly from the hub.

There has thus been outlined, rather broadly, certain embodiments of thedisclosure in order that the detailed description thereof herein may bebetter understood, and in order that the present contribution to the artmay be better appreciated. There are, of course, additional embodimentsthat will be described below and which will form the subject matter ofthe claims appended hereto.

In this respect, before explaining at least one embodiment in detail, itis to be understood that the disclosure is not limited in itsapplication to the details of construction and to the arrangements ofthe components set forth in the following description or illustrated inthe drawings. The disclosed device and method is capable of embodimentsin addition to those described and of being practiced and carried out invarious ways. Also, it is to be understood that the phraseology andterminology employed herein, as well as the abstract, are for thepurpose of description and should not be regarded as limiting.

As such, those skilled in the art will appreciate that the conceptionupon which this disclosure is based may readily be utilized as a basisfor the designing of other structures, methods and systems for carryingout the several purposes of the various embodiments. It is important,therefore, that the claims be regarded as including such equivalentconstructions insofar as they do not depart from the spirit and scope ofthe various embodiments.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a cutaway perspective view of an impeller system in accordancewith an embodiment of the present invention.

FIG. 2 is a detailed view of FIG. 1.

FIG. 3 is a perspective view of a mounting bracket assembly inaccordance with an embodiment of the present invention.

FIG. 4 is a cross sectional view of the impeller system in a firstposition.

FIG. 5 is a cross sectional view of the impeller system in a secondposition.

FIG. 6 is a side view of an impeller assembly in accordance with anembodiment of the present invention.

FIG. 7 is another side view of the impeller assembly depicted in FIG. 6.

FIG. 8 is a cross sectional view of a drive shaft engaged to an impellerhead in accordance with an embodiment of the present invention.

FIG. 9 is a cross sectional view of a locking mechanism for the impellersystem in accordance with an embodiment of the present invention.

FIG. 10 is a more detailed view of the locking mechanism illustrated inFIG. 9.

FIG. 11 is a plan view of the impeller hub in accordance with anembodiment of the present invention.

FIG. 12 is a more detailed view of the impeller the impeller hub.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

An embodiment will now be described with reference to the drawingfigures, in which like reference numerals refer to like partsthroughout. FIG. 1 is a cutaway perspective view of a mixing systemgenerally designated 10. The mixing system 10 comprises a container ormixing vessel 12 having support frame or cage 14 extending at leastpartially around entire missing vessel 12. As illustrated in FIG. 1, themixing system 10 includes an impeller assembly generally designated in16 that includes and impeller 18, sleeve 20 through which a steel ordrive shaft extends 21, and bung closure 22. The impeller system 16further includes a mounting bracket assembly 24, which will be discussedin further detail below, motor mount 26, motor 28, and an output shaft30.

In general, the motor 28 is configured to rotate the steel or driveshaft 30. The shaft 30 is configured for insertion down through the bungclosure 22 and sleeve 20 to engage with the impeller 16. Rotation of thesteel shaft 21 urges the impeller assembly 14 to rotate. Moreparticularly, the impeller 18 is urged to rotate.

Turning specifically to FIGS. 2 and 3, a more detailed view of FIG. 1 isset forth illustrating the mixing assembly 16 which includes themounting bracket assembly 24 and the motor mount 26. As shown in FIG. 2,the mixing assembly 16 comprises upper and lower flanges, 32 and 34respectively, wherein the upper flange 32 is attached the drive shaft 30while the lower flange 34 is attached to the steel shaft 21. As depictedin FIG. 2, the upper flange 32 has a series of slots 36 positioned aboutits periphery while the lower flange 34 has a series of dogs 38positioned about its periphery extending therefrom. During operation,the upper flange 32 and lower flange 34 are releasably connected to oneanother via the above-described dogs and slots. For example, the dogs 38mate with the slots 36 wherein the dogs 38 are inserted into therespective slot 36, and the shafts are rotated such that the dogs engagethe upper flange 32 and retain the upper 32 and lower 34 flanges inplace.

Turning now to FIG. 3, a perspective view of the mounting bracketassembly 24 in accordance with an embodiment of the present invention isillustrated. As shown in FIG. 3, the mounting bracket assembly 24 may begenerally rectangular in geometry having first and second opposing sides40 and 42 along with opposing ends 44 and 46. The mounting bracketassembly further includes rods 41 that extend generally parallel to oneanother between the opposing sides 40 and 42 along with a base plate 48upon which the motor mount 26 and impeller assembly 16 is attached. Thebase plate 48 extends between the first and second sides 40, 42 and hasa circular bracket 50 that assists in aligning the mounting bracketassembly 24 to the motor 12. The base plate 48 has a circular openingthat aligns the bracket to the vessel. The circular bracket 50 has atleast two dogs 52 disposed thereon attaching the motor to the bracket.The mounting bracket assembly 24 further includes latching connectors 54that releasably attach the mounting bracket assembly 24 and thus themotor mount 24 (shown in FIGS. 1 and 2) to the vessel via the cage 14.The bracket assembly 24 attaches the motor mount via a sling leveraction that comprises a pair of side brackets 43 mounted to the sides40, 42 that are actuated via a single lever action 58 that operates torotated the latching connectors 54 into the locked and unlockedposition. The side brackets 43 engage the latching connectors 54 at therods 41. Depending upon the embodiment, the rods 41 may rotate with thelatching connectors 41 or otherwise remain stationary.

Turning now to FIG. 4, a cross sectional view of the impeller system 10in a first position or operating position is depicted. By operatingposition, it is meant that the upper flange 32 and lower flange 34 aremated to one another via the slots 36 and dogs 38, therefor mating thesteel shaft 21 to the drive shaft of the motor. Moreover, due to theaforementioned mating, the steel shaft 21 is translated upward and thusthe bung hole 31 of the vessel 12 is open because the bung closure 20 isdisposed relatively above the bung hole 31 of the vessel. This describeddisposition of the closure 20 is due to the previously describedtranslation of the steel shaft 30.

In this first position, threads 60 disposed upon the bung closure 22 arenot mated to or engaged with threads 62 disposed within the bung hole 31allowing for the shaft 21 to freely rotate. Also shown in FIG. 4, thesteel shaft 21 extends down through the sleeve 20.

Moving on to FIG. 5, whereas FIG. 4 illustrated the assembly in a firstor operating position, FIG. 5 depicts a cross sectional view of theimpeller system 10 in a second position or closed, shipping position. Byclosed position it is meant that the upper flange 32 and lower flange 34are no longer mated to one another via the slots 36 and dogs 38 anddisconnected from one another and in turn, disconnecting the steel shaft21 from the drive shaft of the motor. Moreover, due to theaforementioned disconnection, the steel shaft 21 is removed from thesleeve 20. Furthermore, as illustrated in FIG. 5, the bung closure 22 isnow disposed within the bung hole 31. As illustrated in this secondposition, threads 60 disposed upon the bung closure 22 are mated to orengaged with threads 62 disposed within the bung hole 31 thus sealingthe vessel. As such, the impeller assembly 16 is secured to thecontainer and may be shipped without the likelihood of spillage.

Turning to FIGS. 6 and 7, each is a side view of a portion of theimpeller assembly 16 in accordance with an embodiment of the presentinvention. More particularly, FIGS. 6 and 7 illustrate the portion ofthe impeller assembly extending from the bung hole 31, into the vessel12. As shown in FIG. 6, the impeller assembly 16 is a single sealed unitwith the various components being friction welded or otherwisepermanently affixed to one another. The impeller assembly 14 may be madefrom any suitable material or materials. Suitable materials includethose with sufficient structural rigidity and strength to withstandbeing rotated in fluid and other such loads placed upon the impellerassembly 16. Specific examples of suitable materials include polymerssuch as polyethylene terephthalate (PETE), high-density polyethylene(HDPE), and the like.

Also shown in FIGS. 6 and 7, the impeller 18 includes a plurality ofblades 70 that are substantially air foil in shape. That is, the blades70 are configured to generate a laminar flow as they are driven througha fluid. In this manner, efficient mixing of the fluid within thecontainer 12 may occur. This smooth and airfoil shape is particularlysurprising given that the embodiment shown in FIGS. 6 and 7 is a foldingimpeller to facilitate ingress and egress from the bung hole 31. In thisregard, each of the blades 70 includes a respective hinge 72.

Optionally, the impeller assembly 16 includes a post 74 to rest upon thebottom of the container 12 when the impeller assembly 16 is in thesecond position or shipping position.

Turning now to FIG. 8, a cross sectional view of the steel shaft 28connected to the impeller 18 in accordance with an embodiment of thepresent invention is illustrated. As depicted in FIG. 8, the shaft 21includes detents 80 to receive and retain clips 82 in the impeller 18.In this manner, the shaft 21 is detachably secured to the impeller 18and thus, the impeller assembly 16.

As illustrated in FIG. 8, the sleeve 20 encompasses the steel shaft 21and is plastic welded to the impeller 18. Also, as depicted in FIG. 8,the end of the steel shaft, generally designated 84 has a two machinedflats geometry that assists with the connection to the impeller 18.Moreover, the shaft end 84 has a preferred length to enable the impeller18 to disengage from the shaft 21 and sleeve 20 if the shaft 21 were todetach from the drive shaft or translate or shift downward duringoperation of the mixer assembly 10 preventing engagement of the bungthreads 60, 62 while the motor is rotating the output shaft.

Turning now to FIGS. 9 and 10, cross sectional views of the priordiscussed hinge 72 are depicted. Specifically, the locking mechanism,each generally designated 90, for the blades 70 of the impeller 18 isdepicted in detail. Whereas FIG. 9 shows the hinge 72 in combinationwith the mounting to the shaft 21 and the related connection thereto,FIG. 10 is a detailed depiction of the locking mechanism 90. As shown inboth FIGS. 9 and 10, the blade 70 is oriented in the operating position.By operating position, in general, it is intended that the blades 70 arelocked or retained in the operating position by a locking mechanism 90of varying designs that are capable of retaining the blade 70 in theoperating position, however in one embodiment of the present invention,the locking mechanism is preferably retained by a snap-lock.

As illustrated, in the particular example shown, the snap-lock 90 of thehinge 72 includes a detent or snap down 92 that engages a sear orpositive ramp 94. The detent 92 and sear 94 ‘snap’ lock to retain theblade 70 in the operating position. Moreover, the aforementionedsnap-lock is a single, one time use connection. By one time use it ismeant that when the blade 70 is rotated from the operational position asillustrated, downward or upward as preferred, “shaving” or otherwiseremoval the sear or positive ramp 94 occurs, preventing the blade frombeing locked in the operating position again. Thus, once the blade 70 isforced from the operating position, removing the sear or positive ramp94, the snap-lock may not be utilized again. Also shown in FIGS. 9 and10 the a shaft 96 upon which the blade 70 pivots is shown. The shaft 96appears oblong because the cross sectional view is taken at an obliqueangle relative to the axis of the shaft 96.

Referring now to FIGS. 11 and 12, isometric plan views of the theimpeller 18 in a folded position or non-operational position. Forexample, in this position, the impeller assembly 16 and accompanyingimpeller 18 may be inserted or removed from the vessel 12. As shown inFIGS. 11 and 12, the locking mechanism 90 comprises a detent or snapdown 92 that engages a sear or positive ramp 94. Alternatively, thelocking mechanism may include a design that utilizes a tab to engage aslot in a manner similar to the embodiments previously described.

Also depicted in FIGS. 11 and 12, the impeller 18 includes a fitting 104disposed in a hub 106 of the impeller 18 that receives the end portion84 of the shaft 28. As previously discussed, the end of the steel shaft21, generally designated 84 has a two machined flats geometry thatassists with the connection to the impeller 18. Moreover, the shaft end84 has a preferred length to enable the impeller 18 to disengage fromthe shaft 21 and sleeve 20 if the shaft 21 were to detach from the driveshaft or translate or shift downward during operation of the mixerassembly 10 preventing engagement of the bung threads 60, 62 while themotor is rotating the output shaft. Thus, in the particular exampleshown, the fitting 104 is a double D type fitting. In other examples,the fitting 104 may include a square drive, hexagonal, or the like. Theclips 82 are configured to retain the shaft 28 within the fitting 104.

The many features and advantages of the various embodiments are apparentfrom the detailed specification, and thus, it is intended by theappended claims to cover all such features and advantages that fallwithin the true spirit and scope of the embodiments. Further, sincenumerous modifications and variations will readily occur to thoseskilled in the art, it is not desired to limit the embodiments to theexact construction and operation illustrated and described, andaccordingly, all suitable modifications and equivalents may be resortedto, falling within the scope of the various embodiments.

What is claimed is:
 1. An impeller assembly, comprising: a sleeve havinga first end and a second end; a bung hole closure sealingly disposed atthe first end; and an impeller disposed at the second end, the impellercomprising: a hub; a first blade; a second blade; a first hinge having afirst tab and first detent connected to said hub, wherein said firsthinge pivotally secures said first blade to said hub; and a second hingehaving a second tab and a second detent connected to said hub, whereinsaid second hinge pivotally secures said second blade to said hub. 2.The impeller assembly according to claim 1, further comprising an outputshaft disposed within said sleeve wherein said steel shaft engages saidhub and rotates said impeller.
 3. The impeller assembly accordingly toclaim 2, further comprising a motor assembly attached to said outputshaft wherein said motor assembly rotates said powers said output shaft.4. The impeller assembly according to claim 1, wherein said sleevefurther comprises retaining clips that engage the said impeller.
 5. Theimpeller assembly according to claim 1, wherein said impeller assemblyis a single, apparatus sealed from the outside environment.
 6. Theimpeller assembly, according to claim 3, further comprising: an upperflange connected to said motor assembly; and a lower flange connected tosaid output shaft, wherein said upper flange and said lower flangereleasably connect to one another.
 7. The impeller according to claim 1,wherein said first hinge secures said first blade in an operatingposition, and wherein said second hinge secures said second blade in theoperating position.
 8. The impeller according to claim 1, furthercomprising: a third blade; and a third hinge having a third tab and athird detent connected to said hub, wherein said third hinge pivotallysecures said third blade to said hub.
 9. The impeller according to claim8, wherein said third hinge secures said third blade in the operatingposition.
 10. A mixing apparatus and system comprising: a vessel havinga bung hole disposed on an upper surface thereof; a motor attached tosaid vessel, wherein said motor has a having a shaft; an attachmentassembly to attach the motor to the vessel; and an impeller assemblycomprising: a sleeve having a first end and a second end, the shaftbeing configured to slide within the sleeve; a bung hole closuredisposed at the first end, the bung hole closure being configured tomate with the bung hole; and a sleeve having a first end and a secondend; a bung hole closure sealingly disposed at the first end; and animpeller disposed at the second end, the impeller comprising: a hub; afirst blade; a second blade; a first hinge having a first tab and firstdetent connected to said hub, wherein said first hinge pivotally securessaid first blade to said hub; and a second hinge having a second tab anda second detent connected to said hub, wherein said second hingepivotally secures said second blade to said hub.
 11. The impelleraccording to claim 10, wherein said first hinge secures said first bladein an operating position, and wherein said second hinge secures saidsecond blade in the operating position.
 12. The impeller according toclaim 10, further comprising: a third blade; and a third hinge having athird tab and a third detent connected to said hub, wherein said thirdhinge pivotally secures said third blade to said hub.
 13. The impelleraccording to claim 12, wherein said third hinge secures said third bladein the operating position.
 14. The impeller according to claim 10,wherein said attachment assembly comprises: a frame comprising: a firstend and a second generally opposing one another; a first side thatextends between said for and second ends; a second side that extendsbetween said first and second ends generally parallel to the said firstside; a first rotational rod having first and second ends that extendsbetween said first and said second sides; and a second rotational rodhaving first and second ends that extends between said first and saidsecond sides; a base plate disposed on said frame, wherein said baseplate extends between said first and said second sides and has a boreextending therethrough; a locking lever; a first bracket connected tosaid locking lever and said first rotational rod; a second bracketconnected to said locking lever and said second rotational rod; a firstlatch mounted to said first rotational rod; and a second latch mountedto said second rotational rod.
 15. The attachment assembly according toclaim 14, further comprising: a third latch mounted to said firstrotational rod, wherein said first latch is mounted at the first end ofthe rod and the second latch is mounted at the second end of the rod;and a fourth latch mounted to said second rotational rod, wherein saidthird latch is mounted at the first end of the rod and said fourth latchis mounted at the second end of the rod.
 16. The apparatus according toclaim 14, wherein said locking lever actuates to a first position thatrotates said first and second rotational rods in a first direction andwherein said locking lever actuates to a second position that rotatessaid first and second rotational rods in a opposite second direction.17. The apparatus according to claim 16, wherein said rotation of saidfirst rod causes said first and second latching connectors to swivelbetween a first latch position and a second latch position and whereinsaid rotation of said second rotational rod causes said third and fourthlatching connections to swivel between the first latched position andthe second latched position.
 18. The apparatus according to claim 17,wherein said first position is an unlocked position and wherein saidsecond position is a locked position.
 19. A method for mixing multiplecomponents within a mixing vessel: inserting an impeller assembly intothe vessel, wherein the impeller assembly comprises: a motor attached tosaid vessel, wherein said motor has a shaft; an attachment assembly toattach the motor to the vessel; and a sleeve having a first end and asecond end; a bung hole closure sealingly disposed at the first end; andan impeller disposed at the second end, the impeller comprising: a hub;a first blade; a second blade; a first hinge having a first tab andfirst detent connected to said hub, wherein said first hinge pivotallysecures said first blade to said hub; and a second hinge having a secondtab and a second detent connected to said hub, wherein said second hingepivotally secures said second blade to said hub. translating the secondblade to an operating position by pivoting the first blade whereby thefirst tab engages the first detent such that the first blade extendsoutwardly from the hub; and translating the second blade to theoperating position by pivoting the second blade whereby the second tabengages the second detent such that the second blade extends outwardlyfrom the hub.
 20. A mixing system apparatus, comprising: means forinserting an impeller assembly into the vessel, wherein the impellerassembly comprises: a motor attached to said vessel, wherein said motorhas a shaft; an attachment assembly to attach the motor to the vessel;and a sleeve having a first end and a second end; a bung hole closuresealingly disposed at the first end; and an impeller disposed at thesecond end, the impeller comprising: a hub; a first blade; a secondblade; a first hinge having a first tab and first detent connected tosaid hub, wherein said first hinge pivotally secures said first blade tosaid hub; and a second hinge having a second tab and a second detentconnected to said hub, wherein said second hinge pivotally secures saidsecond blade to said hub means for translating the second blade to anoperating position by pivoting the second blade whereby the second tabengages the second detent such that the second blade extends outwardlyfrom the hub; and means for translating the second blade to theoperating position by pivoting the second blade whereby the second tabengages the second detent such that the second blade extends outwardlyfrom the hub.